Septic tank fabrication system

ABSTRACT

A system for fabricating a septic tank using an outer mold and an inner removable plug, between which hardenable fluid material is poured. Preferably, the plug and mold are positioned with respect to one another in a manner that permits a septic tank to be fabricated in a single pour.

This application is a continuation of U.S. patent application Ser. No.11/388,935, filed Mar. 24, 2006.

BACKGROUND OF THE INVENTION

The present invention pertains to a system for fabricating septic tanks.

Septic tanks typically must be built to conform to regulationspromulgated by one or more respective governmental entities such asstate governments, city governments and other such municipalities, etc.These governmental regulations seek to ensure that septic tanks used incommercial or residential construction are structurally sound and areaccessible for maintenance. For example, many jurisdictions havestandards setting the amount of fluid pressure that commercial andresidential septic tanks must be capable of withstanding. Conformancewith these standards is usually tested by filling a finished septic tankwith an amount of water sufficient to provide the pressure that theseptic tank must be built to withstand.

Existing concrete septic tanks are typically formed by pouring concreteinto an outer mold, and around an interior plug positioned within themold. In order to facilitate the bulk fabrication of septic tanks, it isdesired that both the outer mold and the inner plug be reusable topermit multiple concrete castings, thus reducing the cost of fabricatingseptic tanks. For example, U.S. Pat. No. 3,990,673 to Jones et al. andU.S. Pat. No. 3,687,597 to Lavergne Jr. each disclose respectivereusable systems in which the inner plug and the outer mold may bedetached from the hardened concrete septic tank. Though detachment ofthe outer mold from the hardened concrete is easily accomplished,detachment of the inner plug is often complicated. First, to facilitateremoval of the plug from the interior of the hardened concrete casting,only five sides of the septic tank are poured using the aforementionedmold and plug assembly, with the remaining side poured separately, aswill be later described. Once the concrete surrounding the plug hashardened, the plug must be detached from the five faces of the concretetank and removed through the open side. Detachment of the plug from theconcrete casting in which it is encased may involve either overcoming asubstantial amount of friction generated over the large surface areawhere the plug and the concrete press against each other, oralternatively, some systems, such as the aforementioned patent to Joneset al., employ a complicated structure by which the inner mold iscollapsed inward, and away from the concrete walls to avoid theresisting friction on the plug.

Once the plug has been removed, a cover (or top) of the septic tank issecured to the remainder of the tank enclosure. The cover is typicallyformed by pouring concrete into another mold that provides for anopening through the cover so that the interior of the finished septictank may be accessed for maintenance.

Unfortunately, pouring a septic tank using the previously describedprior art reusable mold and plug systems produces a finished septic tankthat often fails to meet the required standards for fluid pressurecontainment. Specifically, when the tanks are tested by filling themwith water to a required pressure, leakage occurs at the junctionbetween the cover and the poured five-sided enclosure. Essentially, theeconomic incentive to reuse a plug, which dictates that the pouredenclosure have an open side for removing the plug, weakens the septictank structurally at the connection between that poured enclosure andthe separately-poured cover.

What is desired, then, is a system for pouring septic tanks thatincludes a reusable plug and that produces a poured septic tank havingimproved structural strength over septic tanks fabricated using existingsystems.

The foregoing and other objectives, features, and advantages of theinvention will be more readily understood upon consideration of thefollowing detailed description of the invention, taken in conjunctionwith the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows a perspective view of a plug and truss assembly for anexemplary septic tank fabrication system.

FIG. 2 shows an exploded partial view of the plug and truss assembly ofFIG. 1.

FIG. 3 shows a sectional view of an exemplary septic tank fabricationsystem having the plug and truss assembly of FIG. 1 along with an outermold and poured concrete between the plug and the mold.

FIG. 4 shows a sectional view of a hardened septic tank fabricated usingthe septic tank fabrication system of FIG. 1 illustrating the removal ofan outer mold and an inner plug from the hardened septic tank.

FIG. 5 shows a schematic illustration of an exemplary septic tankfabrication system as concrete is being poured to form a septic tank.

FIG. 6 is a cross section of the exemplary septic tank fabricationsystem of FIG. 5 taken along line 6-6.

FIG. 7 is a cross section of the exemplary septic tank fabricationsystem of FIG. 5 taken along line 7-7.

DETAILED DESCRIPTION

Referring to FIGS. 1-3, an exemplary septic tank fabrication system mayinclude a plug and truss assembly 10 and an outer mold 12 (shown in FIG.3) surrounding the plug and truss assembly 10. The outer mold 12 in oneembodiment may be fashioned of multiple walls 14 forming a five-sidedenclosure that may be positioned around the plug and truss assembly 10.In another embodiment, as further described later in this specification,the outer mold 12 may simply be the walls of a hole in the ground. Itshould also be understood that, although the plug and truss assembly 10and the outer mold 12 are each of a substantially rectangular or cubicalconstruction, and thus forming a box-like septic tank, alternateembodiments of the disclosed septic tank fabrication system may utilizemolds and plug assemblies of other desired shapes, e.g. cylindrical,spherical, etc.

Preferably, the plug and truss assembly 10 includes a plug 16, one ormore trusses 18, and one or more retaining members 20 that in thedisclosed plug and truss assembly 10 are shown as hoops having acircular cross section. Alternatively, the retaining members 20 may beof any other desired shape, such as square, etc. Preferably, each hoop20 is positioned between a respective truss 18 and the plug 16, and thetruss 18 preferably includes arms 22 that may rest on the outer mold 12.Each truss 18 may include a positioning mechanism 24 that operates toadjust the height of the plug 16 with respect to the bottom surface 26of the outer mold 12, which may be a wall 14, the bottom surface of ahole in the ground, etc. Thus, the positioning mechanism 24 is used tolift the plug with respect to the outer mold so that concrete 28, whenpoured in the gap 30 between the plug 16 and the outer mold 12 as shownin FIG. 3, forms a septic tank in a single pour.

Referring specifically to FIGS. 5 through 7, fluid concrete or otherhardenable material may be poured into the aforementioned exemplaryseptic tank fabrication system such that the fluid concrete 28 or otherhardenable material flows beneath the plug 16, begins to rise along thesides of the plug 16, and finally begins to flow over the top of theplug 16. At that time, the poured fluid concrete 28 will have two crosssections, as seen in FIGS. 6 and 7, respectively, each mutuallyperpendicular to each other, and each self bounded. The fluid concretewill then flow around the hoops 20 and may then be allowed to harden.Once hardened, the fluid material, such as concrete, will form anintegral septic tank enclosure that will not be weakened by a jointbetween an open-ended enclosure and a separately-formed cover. Thus, aseptic tank fabricated using the disclosed system will be more durableand better able to withstand both testing and operational fluidpressures.

Furthermore, the plug 16 may be of a type that can be reused. Referringto FIGS. 2 and 4, the plug and truss assembly 10 may comprise individualpanels 30 that are each of a size that fits within the opening 42 of theseptic tank formed by a respective hoop 20. The disclosed plug 16includes panels 30 of several shapes. For example, the plug 16 maycomprise corner panels 32, side panels 34, corner panels 35, top panels36, as well as aperture panels 38 over which a respective hoop 20 mayrest as concrete is poured. Each of the panels 30 may be selectively,detachably secured to one or more other panels 30 to form the plug 16.The panels 30 may be secured to each other using any suitable means,such as bolts 40.

The respective hoops 20 preferably have a diameter (or other dimensionif a non-circular retaining member 20 is used) of a size so that theperiphery of the hoop 20 extends beyond that of the aperture panel 38.As can be seen in FIG. 4, this ensures that the aperture panel 38, whendisassembled from the other panels 30, may fit through one of theconcrete openings 42 of the septic tank 28 that is formed by arespective hoop 20. Similarly, each of the panels 30 may preferably besmall enough to fit through an opening 42 of the septic tank 28. Itshould be understood that, although the disclosed plug 16 comprisesindividual panels, each selectively, detachably securable to oneanother, and each sized to fit through an opening 42 of the septic tank,other such systems may include some panels 30 that are of a size that donot fit through an opening 42. In that instance, though some panels mayremain in the interior of the septic tank, the panels 30 that areremoved can be reused and therefore increase the economic efficiency bywhich multiple septic tanks may be fabricated.

One preferred embodiment of the disclosed exemplary septic tank systemutilizes an assembled plug having exterior dimensions of 110 incheslength, 69 inches width, and 56 inches height. In this embodiment, eachcorner panel 32 has two perpendicular sides 44, each having height of 28inches and a 10 inch length l_(c) and connected together by a beveledcorner 46, so as to form a panel having a substantially U-shaped crosssection. Each side panel 34 is substantially L-shaped in cross section,with two perpendicular sides 48 connected by a beveled section 50, sothat the side panel 34 has a width w_(s) of 20.5 inches and a height andlength h_(s) each of 28 inches. The L-shaped cross section of the sidepanels and the U-shaped cross section of the corner panels each give therespective panels around the top periphery of the plug 16 an overhangingcenter of gravity in the assembled plug 16. Thus, when a person isdisassembling the plug 16, each of those upper side and corner panelswill conveniently tilt downwards and inwards once separated from theirneighboring panels, facilitating separation and removal of theindividual panels from the hardened septic tank around the outerperiphery of the plug 16. Similarly, end panels 35 also have an L-shapedcross section, but compared to the side panels 34, have a shortertop-section length of 10 inches, matching that of a corner panel 32.Each of the top panels 36 are 20.5 inches square, as are the aperturepanels 38 which each define an opening 42. The aperture panels 38 mayinclude tabs 52 that each help retain the hoop 20 in position around theopening 42. Similarly, the hoop 20 may include tabs 54 upon whichspacers 55 on a respective truss 18 may rest. Each of the panels 30 maybe formed of any suitable material, such as steel, but are preferablymade of a lightweight material such as aluminum or a fiber-reinforcedcomposite material.

One novel feature of the disclosed exemplary septic tank system is thatthe plug 16 may be assembled to enclose an arbitrary volume by utilizingmore or less panels than that shown in FIG. 1, whose size is describedin the preceding paragraph. As can easily be seen from FIG. 2, forexample, if a septic tank of a larger volume is desired, more sidepanels 34 may simply be inserted into the plug 16 to increase the lengthand/or the width of the plug 16. Similarly, the addition of top panels36 between respective top and bottom side panels 34 around the lateralperiphery of the plug 16 would increase the height of the plug 16, ifdesired. Thus, the disclosed exemplary septic tank system is not onlyeconomically efficient in that it may be reused, it also is efficient inthat it obviates the need to have plugs or plug molds of different sizesin inventory.

The outer mold 12 may comprise five walls 14 attached together to forman open-ended enclosure. Once the concrete 28 or other hardenablematerial poured inside the mold 12 and around the plug 16 has set, eachof the walls 14 may be detached from its neighboring walls 14 andremoved form the outer periphery of the septic tank. The outer mold 12may comprise any appropriate material, such as iron, steel, aluminum,fiber-reinforced composite, etc.

Referring to FIGS. 2 and 3, the truss assembly 18 may comprise a brace60 having two lateral support arms 22 at each end of the brace 60. Thetruss assembly 18 may also include a positioning mechanism 24 comprisinga threaded bolt 64 rotatatably mounted in a mating sleeve 66 and havinga planar flanged end 68 secured to its lower end. As can be seen in FIG.3, each respective truss 18 may be mounted onto the plug 16 so that eachlateral arm 22 of a respective truss 18 rests on a side of the outermold 12. The flanged end 68 is inserted through the opening 42 so as toengage the upper interior surface of the plug 16 around the periphery ofthe opening 42. In this configuration, rotation of the threaded bolt 64will raise the plug 16 relative to the bottom of the mold 12 between afirst, upper position where the hoop 20 presses against the truss 18 anda lower position where the plug 16 rests on the lower wall 14 of themold 12. In this manner, the vertical position of the plug 16 may beadjusted relative to the mold 12 so as to permit fluid material such asconcrete 28 to flow both beneath and above the plug 16, and form aseptic tank in a single pour. Adjustment of the height of the plug 16may also be used to determine the thicknesses of the top and bottomportions of the septic tank, as well. An alternate configuration couldrotatably secure the bolt 64 of the truss 18 to a fixed support abovethe plug and truss assembly 10 and an outer mold 12.

Another novel feature of the disclosed exemplary septic tank system isthat a septic tank could simply be poured in the ground. In thisembodiment, a hole is dug that then serves as the outer mold to the plugand truss assembly 10. The plug 16 is assembled, either in the holeitself or lowered into the hole after being assembled. The trussassemblies 18 are then used to raise the plug 16 relative to the holeand concrete 28 is poured into the hole and around the plug 16. Once theconcrete 28 sets, a person can then climb inside the septic tank anddisassemble the plug 16, removing each panel 30 from the septic tankthrough the opening 42.

It will be understood to those familiar in the art that the foregoingdescription of a septic tank fabrication system is exemplary only, andthe members and methods described therein can be easily modified inscale and configuration. For example, the panels 32 and 34, described ashaving generally U-shaped and L-shaped cross sections, respectively, canbe modified to be larger and/or have cross sections of other shapes.Moreover, though the preceding description of an exemplary method forfabricating a septic omitted discussion of forming required inlet andoutlet valves for a formed septic tank, such details are well known tothose skilled in casting septic tanks.

The terms and expressions that have been employed in the foregoingspecification are used therein as terms of description and not oflimitation, and there is no intention, in the use of such terms andexpressions, of excluding equivalents of the features shown anddescribed or portions thereof, it being recognized that the scope of theinvention is defined and limited only the claims that follow.

The invention claimed is:
 1. An assembly for making a poured septictank, said assembly comprising: (a) a plurality of members eachselectively, detachably securable to one or more other said members soas to form an assembled plug around which concrete may be poured andhardened when said assembled plug is positioned in a surroundingenclosure, said assembled plug defining a first opening into said plug;(b) a retainer positionable proximate a top surface of an assembled saidplug, said retainer capable of retaining hardenable fluid material awayfrom said first opening while said plug is immersed in said hardenablefluid material, said retainer defining a second opening of an area lessthan that of said top surface but sufficient to allow at least one ofsaid members to pass through said second opening; and (c) a brace memberpositionable vertically above the assembled said plug and capable ofsimultaneously pushing said plug to maintain said submerged positionwhile also maintaining an elevated position of said plug with respect toa bottom surface of said surrounding enclosure, where said brace membermay be separated from said plug after said hardenable fluid material hashardened.
 2. The plug assembly of claim 1 where ones of said pluralityof members may selectively be assembled into a plug having a desired oneof a plurality of possible sizes.
 3. The plug assembly of claim 1 wheresaid brace member is capable of securing said retainer to said topsurface.
 4. The plug assembly of claim 3 where said brace memberincludes an adjustment mechanism capable of adjusting the height of anassembled said plug assembly relative to said bottom surface.
 5. Theplug assembly of claim 1 where said brace member includes a flangeportion that engages with an interior surface of said plug to detachablysecure said plug to said brace member at said elevated position whilesaid hardenable fluid material is poured around said plug.
 6. The plugassembly of claim 5 where said brace member includes an adjustmentmechanism capable of variably establishing said elevated position ofsaid plug with respect to said surrounding enclosure.
 7. The plugassembly of claim 1 including at least one said member having at leastone of a generally O-shaped cross section and a generally L-shaped crosssection.
 8. The plug assembly of claim 1 where assembly of plural saidmembers forms a plug assembly having two cross sections, mutuallyperpendicular to each other, and each self bounded.